/*
Copyright (C) 1997-2001 Id Software, Inc.

This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.

See the GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.

*/
/* Modifications
   Copyright 2003-2004 Bytonic Software
   Copyright 2010 Google Inc.
*/
package jake2.render.gl;


import jake2.client.VID;
import jake2.client.entity_t;
import jake2.qcommon.Defines;
import jake2.qcommon.qfiles;
import jake2.render.GLAdapter;
import jake2.render.image_t;
import jake2.util.Math3D;

import java.nio.FloatBuffer;
import java.nio.IntBuffer;
import java.nio.ShortBuffer;

/**
 * Mesh
 *  
 * @author cwei
 */
public abstract class Mesh extends Light {

	// g_mesh.c: triangle model functions
	/*
	=============================================================

	  ALIAS MODELS

	=============================================================
	*/

	static final int NUMVERTEXNORMALS =	162;

	float[][] r_avertexnormals = Anorms.VERTEXNORMALS;
	float[] shadevector = {0, 0, 0};
	float[] shadelight = {0, 0, 0};

	// precalculated dot products for quantized angles
	static final int SHADEDOT_QUANT = 16;

	float[][]	r_avertexnormal_dots = Anorms.VERTEXNORMAL_DOTS;

	float[] shadedots = r_avertexnormal_dots[0];

	/**
	 * GL_LerpVerts
	 * @param nverts
	 * @param ov
	 * @param verts
	 * @param move
	 * @param frontv
	 * @param backv
	 */
	void GL_LerpVerts(int nverts, int[] ov, int[] v, float[] move, float[] frontv, float[] backv )
	{
		FloatBuffer lerp = vertexArrayBuf;
		lerp.limit((nverts << 2) - nverts); // nverts * 3

		int ovv, vv;
			//PMM -- added RF_SHELL_DOUBLE, RF_SHELL_HALF_DAM
		if ( (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) != 0 )
		{
			float[] normal;
			int j = 0;
			for (int i=0 ; i < nverts; i++/* , v++, ov++, lerp+=4 */)
			{
				vv = v[i];
				normal = r_avertexnormals[(vv >>> 24 ) & 0xFF];
				ovv = ov[i];
				lerp.put(j, move[0] + (ovv & 0xFF)* backv[0] + (vv & 0xFF) * frontv[0] + normal[0] * Defines.POWERSUIT_SCALE);
				lerp.put(j + 1, move[1] + ((ovv >>> 8) & 0xFF) * backv[1] + ((vv >>> 8) & 0xFF) * frontv[1] + normal[1] * Defines.POWERSUIT_SCALE);
				lerp.put(j + 2, move[2] + ((ovv >>> 16) & 0xFF) * backv[2] + ((vv >>> 16) & 0xFF) * frontv[2] + normal[2] * Defines.POWERSUIT_SCALE); 
				j += 3;
			}
		}
		else
		{
			int j = 0;
			for (int i=0 ; i < nverts; i++ /* , v++, ov++, lerp+=4 */)
			{
				ovv = ov[i];
				vv = v[i];
				
				lerp.put(j, move[0] + (ovv & 0xFF)* backv[0] + (vv & 0xFF)*frontv[0]);
				lerp.put(j + 1, move[1] + ((ovv >>> 8) & 0xFF)* backv[1] + ((vv >>> 8) & 0xFF)*frontv[1]);
				lerp.put(j + 2, move[2] + ((ovv >>> 16) & 0xFF)* backv[2] + ((vv >>> 16) & 0xFF)*frontv[2]);
				j += 3;
			}
		}
	}
	

	FloatBuffer colorArrayBuf;// = gl.createFloatBuffer(qfiles.MAX_VERTS * 4);
	FloatBuffer vertexArrayBuf;// = gl.createFloatBuffer(qfiles.MAX_VERTS * 3);
	FloatBuffer textureArrayBuf;// = gl.createFloatBuffer(qfiles.MAX_VERTS * 2);

	FloatBuffer colorArrayBuf2;// = gl.createFloatBuffer(qfiles.MAX_VERTS * 4);
	FloatBuffer vertexArrayBuf2;// = gl.createFloatBuffer(qfiles.MAX_VERTS * 3);
	FloatBuffer textureArrayBuf2;// = gl.createFloatBuffer(qfiles.MAX_VERTS * 2);

	
	@Override
	public void init() {
		super.init();
		colorArrayBuf = gl.createFloatBuffer(qfiles.MAX_VERTS * 4);
		vertexArrayBuf = gl.createFloatBuffer(qfiles.MAX_VERTS * 3);
		textureArrayBuf = gl.createFloatBuffer(qfiles.MAX_VERTS * 2);
		

		int FACTOR = 4;
		
		colorArrayBuf2 = gl.createFloatBuffer(qfiles.MAX_VERTS * 4 *FACTOR);
		vertexArrayBuf2 = gl.createFloatBuffer(qfiles.MAX_VERTS * 3 * FACTOR);
		textureArrayBuf2 = gl.createFloatBuffer(qfiles.MAX_VERTS * 2 * FACTOR);

	}

	boolean isFilled = false;
	float[] tmpVec = {0, 0, 0};
	float[][] vectors = {
		{0, 0, 0}, {0, 0, 0}, {0, 0, 0} // 3 mal vec3_t
	};
	
	// stack variable
	private final float[] move = {0, 0, 0}; // vec3_t		
	private final float[] frontv = {0, 0, 0}; // vec3_t
	private final float[] backv = {0, 0, 0}; // vec3_t
	/**
	 * GL_DrawAliasFrameLerp
	 * 
	 * interpolates between two frames and origins
	 * FIXME: batch lerp all vertexes
	 */
	void GL_DrawAliasFrameLerp(qfiles.dmdl_t paliashdr, float backlerp)
	{
		qfiles.daliasframe_t frame = paliashdr.aliasFrames[currententity.frame];

		int[] verts = frame.verts;

		qfiles.daliasframe_t oldframe = paliashdr.aliasFrames[currententity.oldframe];

		int[] ov = oldframe.verts;

		float	alpha;
		if ((currententity.flags & Defines.RF_TRANSLUCENT) != 0)
			alpha = currententity.alpha;
		else
			alpha = 1.0f;

		// PMM - added double shell
		if ( (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) != 0)
		  gl.glDisable( GLAdapter.GL_TEXTURE_2D );

		float frontlerp = 1.0f - backlerp;

		// move should be the delta back to the previous frame * backlerp
		Math3D.VectorSubtract (currententity.oldorigin, currententity.origin, frontv);
		Math3D.AngleVectors (currententity.angles, vectors[0], vectors[1], vectors[2]);

		move[0] = Math3D.DotProduct (frontv, vectors[0]);	// forward
		move[1] = -Math3D.DotProduct (frontv, vectors[1]);	// left
		move[2] = Math3D.DotProduct (frontv, vectors[2]);	// up

		Math3D.VectorAdd (move, oldframe.translate, move);

		for (int i=0 ; i<3 ; i++)
		{
			move[i] = backlerp*move[i] + frontlerp*frame.translate[i];
			frontv[i] = frontlerp*frame.scale[i];
			backv[i] = backlerp*oldframe.scale[i];
		}
		
		// ab hier wird optimiert

		GL_LerpVerts( paliashdr.num_xyz, ov, verts, move, frontv, backv );

		int num_xyz = paliashdr.num_xyz;
		vertexArrayBuf.limit(num_xyz * 3);
		
		//gl.glEnableClientState( GLAdapter.GL_VERTEX_ARRAY );
		gl.glVertexPointer( 3, 0, vertexArrayBuf );

		// PMM - added double damage shell
		if ( (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) != 0)
		{
		  gl.glColor4f( shadelight[0], shadelight[1], shadelight[2], alpha );
		}
		else
		{
		  gl.glEnableClientState( GLAdapter.GL_COLOR_ARRAY );

			FloatBuffer color = colorArrayBuf;
			color.limit(num_xyz * 4);

		  gl.glColorPointer( 4, 0, color );

			//
			// pre light everything
			//
			float l;
			int j = 0;
			for (int i = 0; i < num_xyz; i++ )
			{
				l = shadedots[(verts[i] >>> 24) & 0xFF];
				color.put(j,  l * shadelight[0]);
				color.put(j + 1, l * shadelight[1]);
				color.put(j + 2, l * shadelight[2]);
				color.put(j + 3, alpha);
				j += 4;
			}
		}

		gl.glClientActiveTexture(GL_TEXTURE0);
		FloatBuffer dstTextureCoords = textureArrayBuf;
		
		gl.glTexCoordPointer( 2, 0, dstTextureCoords);
		gl.glEnableClientState( GLAdapter.GL_TEXTURE_COORD_ARRAY);

		int pos = 0;
		int[] counts = paliashdr.counts;
		
		ShortBuffer srcIndexBuf = null;

		FloatBuffer srcTextureCoords = paliashdr.textureCoordBuf;

		int dstIndex = 0;
		int srcIndex = 0;
		int count;
		int mode;
		int size = counts.length;
		for (int j = 0; j < size; j++) {
			dstTextureCoords.limit(num_xyz * 2);

			// get the vertex count and primitive type
			count = counts[j];
			if (count == 0)
				break;		// done
				
			srcIndexBuf = paliashdr.indexElements[j];
			
			mode = GLAdapter.GL_TRIANGLE_STRIP;
			if (count < 0) {
				mode = GLAdapter.GL_TRIANGLE_FAN;
				count = -count;
			}
			srcIndex = pos << 1;
			srcIndex--;
			
			int minIdx = 99999; 
			int maxIdx = 0;
			
			for (int k = 0; k < count; k++) {
				dstIndex = srcIndexBuf.get(k) << 1;
				if (dstIndex < minIdx) {
					minIdx = dstIndex;
				} 
				if (dstIndex > maxIdx) {
					maxIdx = dstIndex;
				}
				dstTextureCoords.put(dstIndex, srcTextureCoords.get(++srcIndex));
				dstTextureCoords.put(++dstIndex, srcTextureCoords.get(++srcIndex));
			}
				
			//gl.updatTCBuffer(dstTextureCoords, minIdx, maxIdx - minIdx + 2);

			dstTextureCoords.limit(maxIdx + 2);
			gl.glTexCoordPointer( 2, 0, dstTextureCoords);
			
			gl.glDrawElements(mode, srcIndexBuf);
			pos += count;
		}

		// PMM - added double damage shell
		if ( (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) != 0 )
		  gl.glEnable( GLAdapter.GL_TEXTURE_2D );

		gl.glDisableClientState( GLAdapter.GL_COLOR_ARRAY );
	}

	
	/**
	 * GL_DrawAliasFrameLerp with drawArrays
	 */
	void GL_DrawAliasFrameLerpDA(qfiles.dmdl_t paliashdr, float backlerp)
	{
		qfiles.daliasframe_t frame = paliashdr.aliasFrames[currententity.frame];

		int[] verts = frame.verts;

		qfiles.daliasframe_t oldframe = paliashdr.aliasFrames[currententity.oldframe];

		int[] ov = oldframe.verts;

		float	alpha;
		if ((currententity.flags & Defines.RF_TRANSLUCENT) != 0)
			alpha = currententity.alpha;
		else
			alpha = 1.0f;

		// PMM - added double shell
		if ( (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) != 0)
		  gl.glDisable( GLAdapter.GL_TEXTURE_2D );

		float frontlerp = 1.0f - backlerp;

		// move should be the delta back to the previous frame * backlerp
		Math3D.VectorSubtract (currententity.oldorigin, currententity.origin, frontv);
		Math3D.AngleVectors (currententity.angles, vectors[0], vectors[1], vectors[2]);

		move[0] = Math3D.DotProduct (frontv, vectors[0]);	// forward
		move[1] = -Math3D.DotProduct (frontv, vectors[1]);	// left
		move[2] = Math3D.DotProduct (frontv, vectors[2]);	// up

		Math3D.VectorAdd (move, oldframe.translate, move);

		for (int i=0 ; i<3 ; i++)
		{
			move[i] = backlerp*move[i] + frontlerp*frame.translate[i];
			frontv[i] = frontlerp*frame.scale[i];
			backv[i] = backlerp*oldframe.scale[i];
		}
		
		// ab hier wird optimiert

		GL_LerpVerts( paliashdr.num_xyz, ov, verts, move, frontv, backv );

		int num_xyz = paliashdr.num_xyz;
		FloatBuffer vertices = vertexArrayBuf;

		// PMM - added double damage shell
		boolean hasColorArray;
		FloatBuffer color = colorArrayBuf;
		hasColorArray = (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) == 0;
		if (hasColorArray) {
			//
			// pre light everything
			//
			float l;
			int j = 0;
			for (int i = 0; i < num_xyz; i++ )
			{
				l = shadedots[(verts[i] >>> 24) & 0xFF];
				color.put(j,  l * shadelight[0]);
				color.put(j + 1, l * shadelight[1]);
				color.put(j + 2, l * shadelight[2]);
				color.put(j + 3, alpha);
				j += 4;
			} 
		} else {
		  gl.glColor4f( shadelight[0], shadelight[1], shadelight[2], alpha );
		}

		int pos = 0;
		int[] counts = paliashdr.counts;
		
		FloatBuffer dstVertexCoords = vertexArrayBuf2;
		FloatBuffer dstColors = colorArrayBuf2;

		dstVertexCoords.clear();
		dstColors.clear();
		
		int count;
		int mode;
		int size = counts.length;
		for (int j = 0; j < size; j++) {
			// get the vertex count and primitive type
			count = counts[j];
			if (count == 0)
				break;		// done
				
			ShortBuffer srcIndexBuf = paliashdr.indexElements[j];
			
			if (count < 0) {
				count = -count;
			}
			
			for (int k = 0; k < count; k++) {
				int srcIndex = srcIndexBuf.get(k);
				if (hasColorArray) {
					int cSrcIndex = srcIndex * 4;
					dstColors.put(color.get(cSrcIndex));
					dstColors.put(color.get(cSrcIndex+1));
					dstColors.put(color.get(cSrcIndex+2));
					dstColors.put(color.get(cSrcIndex+3));
				}
				int vSrcIndex = srcIndex * 3;
				dstVertexCoords.put(vertices.get(vSrcIndex));
				dstVertexCoords.put(vertices.get(vSrcIndex+1));
				dstVertexCoords.put(vertices.get(vSrcIndex+2));
			}
				
			//gl.updatTCBuffer(dstTextureCoords, minIdx, maxIdx - minIdx + 2);
			pos += count;
		}

		if (hasColorArray) {
			gl.glEnableClientState( GLAdapter.GL_COLOR_ARRAY );
			dstColors.flip();
			gl.glColorPointer(4, 0, dstColors);
		}
		
		gl.glClientActiveTexture(GL_TEXTURE0);	
		gl.glEnableClientState( GLAdapter.GL_TEXTURE_COORD_ARRAY);

		FloatBuffer tc0 = paliashdr.textureCoordBuf;
		int limit = tc0.limit();
		tc0.limit(tc0.position() + pos * 2);
		gl.glVertexAttribPointer(GLAdapter.ARRAY_TEXCOORD_0, 2, GLAdapter.GL_FLOAT, false, 0, 0,
				paliashdr.textureCoordBuf, paliashdr.staticTextureBufId);
		tc0.limit(limit);
		
		dstVertexCoords.flip();
		gl.glVertexPointer(3, 0, dstVertexCoords);

		pos = 0;
		for (int j = 0; j < size; j++) {
			// get the vertex count and primitive type
			count = counts[j];
			if (count == 0)
				break;		// done
				
			mode = GLAdapter.GL_TRIANGLE_STRIP;
			if (count < 0) {
				mode = GLAdapter.GL_TRIANGLE_FAN;
				count = -count;
			}
			gl.glDrawArrays(mode, pos, count);
			pos += count;
		}

		
		// PMM - added double damage shell
		if ( (currententity.flags & ( Defines.RF_SHELL_RED | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE | Defines.RF_SHELL_HALF_DAM)) != 0 )
		  gl.glEnable( GLAdapter.GL_TEXTURE_2D );

		gl.glDisableClientState( GLAdapter.GL_COLOR_ARRAY );
	}
	
	
	private final float[] point = {0, 0, 0};
	/**
	 * GL_DrawAliasShadow
	 */
	void GL_DrawAliasShadow(qfiles.dmdl_t paliashdr, int posenum)
	{
		float lheight = currententity.origin[2] - lightspot[2];
//		qfiles.daliasframe_t frame = paliashdr.aliasFrames[currententity.frame];
		int[] order = paliashdr.glCmds;
		float height = -lheight + 1.0f;
		
		int orderIndex = 0;
		int index = 0;

		// TODO shadow drawing with vertex arrays

		int count;
		while (true)
		{
			// get the vertex count and primitive type
			count = order[orderIndex++];
			if (count == 0)
				break;		// done
			if (count < 0)
			{
				count = -count;
				gl.glBegin (GLAdapter.GL_TRIANGLE_FAN);
			}
			else
			  gl.glBegin (GLAdapter.GL_TRIANGLE_STRIP);

			do
			{
				index = order[orderIndex + 2] * 3;
				point[0] = vertexArrayBuf.get(index);
				point[1] = vertexArrayBuf.get(index + 1);
				point[2] = vertexArrayBuf.get(index + 2);
					
				point[0] -= shadevector[0]*(point[2]+lheight);
				point[1] -= shadevector[1]*(point[2]+lheight);
				point[2] = height;
				gl.glVertex3f(point[0], point[1], point[2]);

				orderIndex += 3;

			} while (--count != 0);

			gl.glEnd ();
		}	
	}

//	TODO sync with jogl renderer. hoz
	// stack variable
	private final float[] mins = { 0, 0, 0 };
	private final float[] maxs = { 0, 0, 0 };
	/**
	 * R_CullAliasModel
	*/
	boolean R_CullAliasModel(entity_t e) {
		qfiles.dmdl_t paliashdr = (qfiles.dmdl_t) currentmodel.extradata;

		if ((e.frame >= paliashdr.num_frames) || (e.frame < 0)) {
			VID.Printf(Defines.PRINT_ALL, "R_CullAliasModel " + currentmodel.name + ": no such frame " + e.frame + '\n');
			e.frame = 0;
		}
		if ((e.oldframe >= paliashdr.num_frames) || (e.oldframe < 0)) {
			VID.Printf(Defines.PRINT_ALL, "R_CullAliasModel " + currentmodel.name + ": no such oldframe " + e.oldframe + '\n');
			e.oldframe = 0;
		}

		qfiles.daliasframe_t pframe = paliashdr.aliasFrames[e.frame];
		qfiles.daliasframe_t poldframe = paliashdr.aliasFrames[e.oldframe];

		/*
		** compute axially aligned mins and maxs
		*/
		if (pframe == poldframe) {
			for (int i = 0; i < 3; i++) {
				mins[i] = pframe.translate[i];
				maxs[i] = mins[i] + pframe.scale[i] * 255;
			}
		} else {
			float thismaxs, oldmaxs;
			for (int i = 0; i < 3; i++) {
				thismaxs = pframe.translate[i] + pframe.scale[i] * 255;

				oldmaxs = poldframe.translate[i] + poldframe.scale[i] * 255;

				if (pframe.translate[i] < poldframe.translate[i])
					mins[i] = pframe.translate[i];
				else
					mins[i] = poldframe.translate[i];

				if (thismaxs > oldmaxs)
					maxs[i] = thismaxs;
				else
					maxs[i] = oldmaxs;
			}
		}

		/*
		** compute a full bounding box
		*/
		float[] tmp;
		for (int i = 0; i < 8; i++) {
			tmp = bbox[i];
			if ((i & 1) != 0)
				tmp[0] = mins[0];
			else
				tmp[0] = maxs[0];

			if ((i & 2) != 0)
				tmp[1] = mins[1];
			else
				tmp[1] = maxs[1];

			if ((i & 4) != 0)
				tmp[2] = mins[2];
			else
				tmp[2] = maxs[2];
		}

		/*
		** rotate the bounding box
		*/
		tmp = mins;
		Math3D.VectorCopy(e.angles, tmp);
		tmp[YAW] = -tmp[YAW];
		Math3D.AngleVectors(tmp, vectors[0], vectors[1], vectors[2]);

		for (int i = 0; i < 8; i++) {
			Math3D.VectorCopy(bbox[i], tmp);

			bbox[i][0] = Math3D.DotProduct(vectors[0], tmp);
			bbox[i][1] = -Math3D.DotProduct(vectors[1], tmp);
			bbox[i][2] = Math3D.DotProduct(vectors[2], tmp);

			Math3D.VectorAdd(e.origin, bbox[i], bbox[i]);
		}

		int f, mask;
		int aggregatemask = ~0; // 0xFFFFFFFF

		for (int p = 0; p < 8; p++) {
			mask = 0;

			for (f = 0; f < 4; f++) {
				float dp = Math3D.DotProduct(frustum[f].normal, bbox[p]);

				if ((dp - frustum[f].dist) < 0) {
					mask |= (1 << f);
				}
			}

			aggregatemask &= mask;
		}

		if (aggregatemask != 0) {
			return true;
		}

		return false;
	}


	// bounding box
	float[][] bbox = {
		{0, 0, 0}, {0, 0, 0}, {0, 0, 0}, {0, 0, 0},
		{0, 0, 0}, {0, 0, 0}, {0, 0, 0}, {0, 0, 0}
	};

//	TODO sync with jogl renderer. hoz
	/**
	 * R_DrawAliasModel
	 */
	void R_DrawAliasModel(entity_t e)
	{
		if ( ( e.flags & Defines.RF_WEAPONMODEL ) == 0)
		{
			if ( R_CullAliasModel(e) )
				return;
		}

		if ( (e.flags & Defines.RF_WEAPONMODEL) != 0 )
		{
			if ( r_lefthand.value == 2.0f )
				return;
		}

		qfiles.dmdl_t paliashdr = (qfiles.dmdl_t)currentmodel.extradata;

		//
		// get lighting information
		//
		// PMM - rewrote, reordered to handle new shells & mixing
		// PMM - 3.20 code .. replaced with original way of doing it to keep mod authors happy
		//
		int i;
		if ( (currententity.flags & ( Defines.RF_SHELL_HALF_DAM | Defines.RF_SHELL_GREEN | Defines.RF_SHELL_RED | Defines.RF_SHELL_BLUE | Defines.RF_SHELL_DOUBLE )) != 0 )
		{
			Math3D.VectorClear(shadelight);
			if ((currententity.flags & Defines.RF_SHELL_HALF_DAM) != 0)
			{
					shadelight[0] = 0.56f;
					shadelight[1] = 0.59f;
					shadelight[2] = 0.45f;
			}
			if ( (currententity.flags & Defines.RF_SHELL_DOUBLE) != 0 )
			{
				shadelight[0] = 0.9f;
				shadelight[1] = 0.7f;
			}
			if ( (currententity.flags & Defines.RF_SHELL_RED) != 0 )
				shadelight[0] = 1.0f;
			if ( (currententity.flags & Defines.RF_SHELL_GREEN) != 0 )
				shadelight[1] = 1.0f;
			if ( (currententity.flags & Defines.RF_SHELL_BLUE) != 0 )
				shadelight[2] = 1.0f;
		}

		else if ( (currententity.flags & Defines.RF_FULLBRIGHT) != 0 )
		{
			for (i=0 ; i<3 ; i++)
				shadelight[i] = 1.0f;
		}
		else
		{
			R_LightPoint (currententity.origin, shadelight);

			// player lighting hack for communication back to server
			// big hack!
			if ( (currententity.flags & Defines.RF_WEAPONMODEL) != 0 )
			{
				// pick the greatest component, which should be the same
				// as the mono value returned by software
				if (shadelight[0] > shadelight[1])
				{
					if (shadelight[0] > shadelight[2])
						r_lightlevel.value = 150*shadelight[0];
					else
						r_lightlevel.value = 150*shadelight[2];
				}
				else
				{
					if (shadelight[1] > shadelight[2])
						r_lightlevel.value = 150*shadelight[1];
					else
						r_lightlevel.value = 150*shadelight[2];
				}
			}
		
			if ( gl_monolightmap.string.charAt(0) != '0' )
			{
				float s = shadelight[0];

				if ( s < shadelight[1] )
					s = shadelight[1];
				if ( s < shadelight[2] )
					s = shadelight[2];

				shadelight[0] = s;
				shadelight[1] = s;
				shadelight[2] = s;
			}
		}

		if ( (currententity.flags & Defines.RF_MINLIGHT) != 0 )
		{
			for (i=0 ; i<3 ; i++)
				if (shadelight[i] > 0.1f)
					break;
			if (i == 3)
			{
				shadelight[0] = 0.1f;
				shadelight[1] = 0.1f;
				shadelight[2] = 0.1f;
			}
		}

		if ( (currententity.flags & Defines.RF_GLOW) != 0 )
		{	// bonus items will pulse with time
			float	scale;
			float	min;

			scale = (float)(0.1f * Math.sin(r_newrefdef.time*7));
			for (i=0 ; i<3 ; i++)
			{
				min = shadelight[i] * 0.8f;
				shadelight[i] += scale;
				if (shadelight[i] < min)
					shadelight[i] = min;
			}
		}

		// =================
		// PGM	ir goggles color override
		if ( (r_newrefdef.rdflags & Defines.RDF_IRGOGGLES) != 0 && (currententity.flags & Defines.RF_IR_VISIBLE) != 0)
		{
			shadelight[0] = 1.0f;
			shadelight[1] = 0.0f;
			shadelight[2] = 0.0f;
		}
		// PGM	
		// =================

		shadedots = r_avertexnormal_dots[((int)(currententity.angles[1] * (SHADEDOT_QUANT / 360.0))) & (SHADEDOT_QUANT - 1)];
	
		float an = (float)(currententity.angles[1]/180*Math.PI);
		shadevector[0] = (float)Math.cos(-an);
		shadevector[1] = (float)Math.sin(-an);
		shadevector[2] = 1;
		Math3D.VectorNormalize(shadevector);

		//
		// locate the proper data
		//

		c_alias_polys += paliashdr.num_tris;

		//
		// draw all the triangles
		//
		if ( (currententity.flags & Defines.RF_DEPTHHACK) != 0) // hack the depth range to prevent view model from poking into walls
		  gl.glDepthRange(gldepthmin, (float) (gldepthmin + 0.3*(gldepthmax-gldepthmin)));

		if ( (currententity.flags & Defines.RF_WEAPONMODEL) != 0 && (r_lefthand.value == 1.0f) )
		{
		  gl.glMatrixMode( GLAdapter.GL_PROJECTION );
		  gl.glPushMatrix();
		  gl.glLoadIdentity();
		  gl.glScalef( -1, 1, 1 );
			MYgluPerspective( r_newrefdef.fov_y, ( float ) r_newrefdef.width / r_newrefdef.height,  4,  4096);
			gl.glMatrixMode( GLAdapter.GL_MODELVIEW );

			gl.glCullFace( GLAdapter.GL_BACK );
		}

		gl.glPushMatrix ();
		e.angles[PITCH] = -e.angles[PITCH];	// sigh.
		R_RotateForEntity (e);
		e.angles[PITCH] = -e.angles[PITCH];	// sigh.

		
		
		image_t		skin;
		// select skin
		if (currententity.skin != null)
			skin = currententity.skin;	// custom player skin
		else
		{
			if (currententity.skinnum >= qfiles.MAX_MD2SKINS)
				skin = currentmodel.skins[0];
			else
			{
				skin = currentmodel.skins[currententity.skinnum];
				if (skin == null)
					skin = currentmodel.skins[0];
			}
		}
		if (skin == null)
			skin = r_notexture;	// fallback...
		GL_Bind(skin.texnum);

		// draw it

		gl.glShadeModel (GLAdapter.GL_SMOOTH);

		GL_TexEnv( GLAdapter.GL_MODULATE );
		if ( (currententity.flags & Defines.RF_TRANSLUCENT) != 0 )
		{
		  gl.glEnable (GLAdapter.GL_BLEND);
		}


		if ( (currententity.frame >= paliashdr.num_frames) 
			|| (currententity.frame < 0) )
		{
			VID.Printf (Defines.PRINT_ALL, "R_DrawAliasModel " + currentmodel.name +": no such frame " + currententity.frame + '\n');
			currententity.frame = 0;
			currententity.oldframe = 0;
		}

		if ( (currententity.oldframe >= paliashdr.num_frames)
			|| (currententity.oldframe < 0))
		{
			VID.Printf (Defines.PRINT_ALL, "R_DrawAliasModel " + currentmodel.name +": no such oldframe " + currententity.oldframe + '\n');
			currententity.frame = 0;
			currententity.oldframe = 0;
		}

		if ( r_lerpmodels.value == 0.0f)
			currententity.backlerp = 0;
		
		GL_DrawAliasFrameLerpDA(paliashdr, currententity.backlerp);

		GL_TexEnv( GLAdapter.GL_REPLACE );
		gl.glShadeModel (GLAdapter.GL_FLAT);

		gl.glPopMatrix ();

		if ( ( currententity.flags & Defines.RF_WEAPONMODEL ) != 0 && ( r_lefthand.value == 1.0F ) )
		{
		  gl.glMatrixMode( GLAdapter.GL_PROJECTION );
		  gl.glPopMatrix();
		  gl.glMatrixMode( GLAdapter.GL_MODELVIEW );
		  gl.glCullFace( GLAdapter.GL_FRONT );
		}

		if ( (currententity.flags & Defines.RF_TRANSLUCENT) != 0 )
		{
		  gl.glDisable (GLAdapter.GL_BLEND);
		}

		if ( (currententity.flags & Defines.RF_DEPTHHACK) != 0)
		  gl.glDepthRange (gldepthmin, gldepthmax);

		if ( gl_shadows.value != 0.0f && (currententity.flags & (Defines.RF_TRANSLUCENT | Defines.RF_WEAPONMODEL)) == 0)
		{
		  gl.glPushMatrix ();
			R_RotateForEntity (e);
			gl.glDisable (GLAdapter.GL_TEXTURE_2D);
			gl.glEnable (GLAdapter.GL_BLEND);
			gl.glColor4f (0,0,0,0.5f);
			GL_DrawAliasShadow (paliashdr, currententity.frame );
			gl.glEnable (GLAdapter.GL_TEXTURE_2D);
			gl.glDisable (GLAdapter.GL_BLEND);
			gl.glPopMatrix ();
		}
		gl.glColor4f (1,1,1,1);
	}
}
